1 research outputs found
Shift in Mass Transfer of Wastewater Contaminants from Microplastics in the Presence of Dissolved Substances
In
aqueous environments, hydrophobic organic contaminants are often
associated with particles. Besides natural particles, microplastics
have raised public concern. The release of pollutants from such particles
depends on mass transfer, either in an aqueous boundary layer or by
intraparticle diffusion. Which of these mechanisms controls the mass-transfer
kinetics depends on partition coefficients, particle size, boundary
conditions, and time. We have developed a semianalytical model accounting
for both processes and performed batch experiments on the desorption
kinetics of typical wastewater pollutants (phenanthrene, tonalide,
and benzophenone) at different dissolved-organic-matter concentrations,
which change the overall partitioning between microplastics and water.
Initially, mass transfer is externally dominated, while finally, intraparticle
diffusion controls release kinetics. Under boundary conditions typical
for batch experiments (finite bath), desorption accelerates with increasing
partition coefficients for intraparticle diffusion, while it becomes
independent of partition coefficients if film diffusion prevails.
On the contrary, under field conditions (infinite bath), the pollutant
release controlled by intraparticle diffusion is not affected by partitioning
of the compound while external mass transfer slows down with increasing
sorption. Our results clearly demonstrate that sorption/desorption
time scales observed in batch experiments may not be transferred to
field conditions without an appropriate model accounting for both
the mass-transfer mechanisms and the specific boundary conditions
at hand